US5576873A - Telecommunications switch architecture - Google Patents
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Definitions
- This invention relates to telecommunications switch architecture, and in particular but not exclusively to architectures for use in multi-service environments rather than just the conventional voice traffic as in a PSTN (Public Switched Telephone Network)
- PSTN Public Switched Telephone Network
- Speech and data signals are more and more being transmitted optically rather than electrically, however switching is performed in the electrical mode.
- Optical switching has been suggested particularly in order to obviate the need for opto-electronic interfaces which add to the system complexity and cost.
- the relatively low operating speed of currently available optical switch elements places a severe restriction on the system bit rate.
- the present invention is concerned with a switching architecture that can be embodied in both optical and electronic form
- TST Time-Space-Time
- STS Space-Time-Space
- SDH Synchronous Digital Hierarchy
- ATM Asynchronous Transfer Mode
- ATM cells and their headers are, once the frame overhead is removed, contiguous bits in the bit stream, whereas STM information at, say the 2 Mbit/s level is distributed throughout the frame. This means that incoming ATM information can be switched on the fly but a frame store is necessary before STM information can be switched.
- the BERKOM project uses an ATM switch (H. Armbruster et al "Phasing-in the universal broadband ISDN: initial trials for examining ATM applications and ATM systems" Integrated broadband Services and Networks. lEE Publication No. 329, October 1990, pp 200-205).
- Gauss is an ATM switch (R. J. F. de Vries "Guass: a single-stage ATM switch with output buffering”. Integrated Broadband Services and Networks, lEE Conference Publication No. 329, October 1990, pp 248-252.
- the ATMOSPHERIC switch also contains an overload policing function to prevent users trying to use more resources than were negotiated at call set-up time.
- Knockout switch Another known switch, which is a packet only switch is Knockout (Y-S Yen et al "The Knockout Switch: a simple, modular architecture for high-performance packet switching" lEE Journal on selected Areas in Communication, Vol SAC-5, No. 8, October 1987, pp 1274-1283).
- the Knockout switch uses a fully interconnected switch fabric topology (i.e. each input has a direct path to every output) so that no switch blocking occurs where packets destined for one input interfere with (block or delay) packets going to different outputs. It is only at each output of the switch that one encounters the unavoidable congestion caused by multiple packets simultaneously arriving on different inputs all destined for the same output.
- the Knockout switch uses a concentrator design at each output to reduce the number of separate buffers needed to receive simultaneously arriving packets.
- a shared buffer architecture provides complete sharing of all buffer memory at each output and ensures that all packets are placed on the output line on a first-in first-out basis.
- Knockout appears to be the first switch design that used a broadcast approach, i.e. all the incoming channels broadcast their outputs to all the outgoing channels.
- Gauss also uses a broadcast approach which gives it its non-blocking property.
- Gauss is specific to the RACE environment and is modular at the STM-1 level.
- a switching architecture including a plurality of incoming links and a plurality of outgoing links, for switching data between the incoming and outgoing links, which data is in serial form on said incoming links, the architecture further including means for converting said serial data into parallel form and comprising, for each incoming link, address decode and memory write means; one or more input memory blocks in which said data is stored at specific addresses; means for replicating the data whereby all incoming data are available for all or selected outgoing links, said converting, storing and replicating means being interconnected whereby the storage occurs before the replication or concurrently therewith and the replication occurs when the data is in serial or parallel form; means for each replication, for transferring data from one of said memory blocks to the appropriate one of said outgoing links, which transfer means is either such as to read directly from the relevant address in said input memory blocks or such as to transfer the content of all or part of said input memory blocks simultaneously en bloc and in parallel to a plurality of output memory blocks, each associated with a respective outgoing link; and means for converting said serial data into parallel
- FIG. 1 is a schematic diagram of an optical packet switch
- FIG. 2 is a timing diagram for the switch of FIG. 1;
- FIG. 3 illustrates a general case of a smart pixel
- FIG. 4 illustrates an embodiment of image replicating optical switch for use in the packet switch of FIG. 1;
- FIGS. 5 and 5a illustrate an input packet page formatter (PPF) for the packet switch of FIG. 1;
- PPF packet page formatter
- FIGS. 6 and 6a illustrate an output packet page sequencer (PPS) for the packet switch of FIG. 1;
- PPS packet page sequencer
- FIGS. 7a and 7b illustrate schematic diagrams for an Optical Space switch, ETOSET (Simple Replication) and ETOSET (Assigned Input Memory) respectively;
- FIG. 8 illustrates schematically an ETOSET switch
- FIGS. 9a and 9b indicate link timing and memory timing, respectively.
- FIGS. 10a and 10b indicate memory utilisation charts, an input memory chart with destination addresses and an output memory chart with source addresses;
- FIG. 11 indicates input memory assignments
- FIG. 12 illustrates schematically a SER switch and in particular indicates broadcast to replicated memory
- FIG. 13 illustrates the internal organisation of a memory block
- FIG. 14 illustrates a revised schematic for ETOSET
- FIGS. 15a and 15b illustrate source memory organisation for a parallel read-out and serial read-out, respectively;
- FIG. 16 illustrates memory assignment for an input memory
- FIG. 17 illustrates memory assignment for an input memory after shuffling
- FIG. 18 is a table comparing ETOSET memory requirements without and with a shuffle
- FIG. 19 illustrates segregation of input memory into designated destruction areas
- FIG. 20 illustrates schematically the three planes of the switch
- FIG. 21 illustrates control area communications with four links
- FIG. 22 illustrates schematically SER, broadcast to replicated memory, with shuffle
- FIG. 23 is a table comparing SER memory requirements without and with a shuffle.
- FIGS. 24a and 24b illustrate output memory and an example of packing process for link 4, in particular representation of incoming datastream and memory occupancy at the time slot 5, respectively.
- the switching architectures of the present invention are based on the principle of replication or broadcasting of some or all incoming information from each input port to all output switch ports. The concept is first described hereinafter in terms of a packet switch.
- FIG. 1 comprises a fast packet switch based on free space optics and spatial light modulators.
- fast ferro electric liquid crystal integrated with silicon VLSI technology can be employed for the latter, see for example GB Application No. 90/3593.0 (Ser. No. 2233469A) (W A Crossland 57-9-1) which discusses various aspects of so-called smart pixels.
- FIG. 3 illustrates the general case of a smart pixel which as will be appreciated is a hybrid electro-optic arrangement. Depending on its function the smart pixel may not need all of the electronic inputs and outputs and the optical input can be very simple, such as in the case of optically accessed Random Access Memory (RAM) cells.
- RAM Random Access Memory
- An optical input 1 applied to photodetector pad 2 serves to trigger an electronic logic unit 3 if it is above a predetermined threshold value set in threshold amplifier 4.
- the output of the logic unit 3 is applied to driver 5 which drives a light modulator pad 6 associated with a liquid crystal element (not shown) to change the state of the liquid crystal accordingly.
- a read beam 7 can thus result in an optical output 8 if the liquid crystal is in the appropriate state.
- a number of different technologies may be used to construct smart pixel arrays.
- smart spatial light modulators made by overlaying ferro electric liquid crystal layers over silicon VLSI die. This is called FELC/VLSI technology. (N Collings, W A Crossland, P J Ayliffe, D E Vass, I Underwood “Evolutionary development of advanced liquid crystal spatial light modulators” Appl. Opt 28, pp 4740-4747, 1989).
- the packet switch of FIG. 1 comprises a time sequence interchanger and router switch using smart SLM (Spatial Light Modulator) input and output planes.
- the switch is shown for two fibres, four packets and a single wavelength and is by way of example only.
- Fast serial data as carried on input optical fibre 10 is taken from the time domain applied to a photodiode 12 and formatted into spatially arranged pages on a packet page formatter (PPF) 11.
- PPF packet page formatter
- Each PPF spatially stores four packets from an input fibre.
- Each such page is then read by a read laser 18 and transmitted (switched) en bloc and in parallel using image replicating optics 13.
- the switched and replicated signals are directed to a packet page sequencer (PPS) 14 from which serial signals are derived to drive a respective modulator 15, whereby light output from a laser 16 is modulated prior to being input to an output fibre 17 in order to produce another serial data stream.
- PPS packet page sequencer
- the modulator 15 is a multiquantum well device.
- the data formatting is illustrated using shift registers, which in practice may not be sufficiently efficient, however, this illustration is by way of example only and to indicate the principles of an optical packet switch.
- the planes comprising the formatter 11 and sequencer 14 may be considered as optically accessed memory i.e.
- FIG. 1 may be likened in principle with an all-electronic system in which data is demultiplexed down, stored in RAM, rearranged and then multiplexed back up as necessary. From this viewpoint, optics is used to achieve very large pin outs in and out of the electronic memory. It also enables the rearrangement and replication of data packets to occur instantaneously, once the pattern has been set up, via the parallel optical interconnect switch.
- FIG. 2 A timing diagram for the arrangement of FIG. 1 is shown in FIG. 2 which illustrates the principles of both routing and time slot interchange. Two routing channels are shown along with time slot interchange between four cells.
- the time T available to set up the optical switch is less than or equal to N times the packet or cell length.
- N is the number of different packets stored on the input PPF.
- N is the number of replications of each different packet stored on the input PPF.
- Each PPF spatially stores 4 packets from an input fibre whereas each PPS serialises a switched packet for an output fibre.
- FIG. 4 An example of an image replicating optical crossbar switch is illustrated in FIG. 4.
- the design shown schematically in FIG. 4 is a matrix-matrix multiplier switch.
- the diagram implies that it can switch data patterns, shown here as images, as well as single channels.
- the design also has advantages of efficiency over matrix-vector designs.
- the optical arrangement necessary is described in more detail in "A Compact and Scalable Free-Space Optical Crossbar" A G Kirk, W A Crossland, T J Hall, 3rd International Conference on Holographic Systems, Components and Applications, 16-18 September 1991, Edinburgh UK.
- the spatially distributed input information is represented by symbols.
- Holographic fan-out optics 21 replicates an input array 20 (PPF) with N inputs N times.
- the holographic fan-out may be comprised by use of parallel diffractive optics in partial Fourier plane array generators as discussed in the Kirk paper. Such an arrangement has the major property, referred to above, that it can handle images (blocks of data) rather than just single channels.
- a FELC SLM 22 with N 2 shutters comprising an FELC optical cross bar performs the routing (switching) as a result of the shutters being "open” or “closed” as appropriate, and a fan-in optic lens array 23 directs signals to the output array 24 (output page sequencer) for subsequent retransmission in serial form.
- Optical crossbar switches are devices for connecting N inputs to one or more of N outputs and may include a crossbar matrix (spatial light modulator) which determines the routing of inputs to outputs.
- a matrix-vector optical crossbar switch is described in A R Dias, R F Kalman, J W Goodman, A A Sawchuck, "Fibre optical crossbar switch with broadcast capability” Opt. Eng. 27(11) pp 955-960, 1988. See also, for example, our GB Patent Application No. 90 10692.3 (Ser. No. 2243967A) (W A Crossland 58-1-1) which discusses various aspects and embodiments of optical crossbar switches based on the principle of the matrix vector multipliers. These principles also apply to matrix-matrix switches of the kind discussed here.]
- packet switches are thus the smart pixel devices, the page formatters and page serialisers that form the input and output planes, and the SLM at the heart of the optical interconnect. They may all be envisaged as FELV/VLSI devices. Bit level processing (shifting) occurs within the electronic domain but within small electronic pixels or islands, whereas optics is used to switch the spatially paged information.
- the input plane is shown in further detail in FIGS. 5 and 5a.
- the arrangement functions as a very fast electronic shift register organised as a two dimensional page.
- Incoming serial optical data is received by photodiode 31 and corresponding electrical signals are fed via threshold and serialising logic 32 to a series arrangement of electronic logic elements 33 each having a respective driver 34 and optical modulating pads 35, as indicated in greater detail in FIG. 5a.
- Each stage of the shift register is itself a smart pixel with its own FELC optical modulator. No photodetectors are required at the pixel level on the PPF. The modulators do not have to operate at the bit rate but only at the slower page rate.
- Each logic unit 33 of FIG. 5 may include more than one memory cell to facilitate simultaneous read-in and read-out of data (as shown in FIG. 15).
- the output plane (PPS) of FIGS. 6 and 6a reverses the procedure of the input plane and carries out a parallel to serial conversion using a shift register structure in which each stage has an associated photodetector 41 to read the incoming data image, a threshold amplifier 42 and an electronic logic unit 43. There is slow transfer of threshold data to the units 43 but high speed electrical transfer between units 43 at the full data rate.
- the sequential data output is fed via control logic 44 to a MQW modulator 45 which is used as described above.
- Advantageously BiCMOS technology is employed for the fast silicon backplane structure, since bipolar technology is required for fast shift registers and the CMOS processing allows photodetectors to be integrated into smart pixel arrays.
- the switch described above is a fast packet switch based on FELC/VLSI technology.
- the same basic principle of replication or broadcasting of incoming information from each incoming switch port to all outgoing switch ports can, for example, be employed to achieve a switch capable of interfacing with transmission networks using the synchronous digital hierarchy (SDH) that can switch multiple links running at the basic 155 Mbit/s SDH rate (STM-1) using synchronous and asynchronous time division (STD and ATD) techniques.
- SDH synchronous digital hierarchy
- STM-1 basic 155 Mbit/s SDH rate
- STD and ATD synchronous and asynchronous time division
- STM Synchronous Transfer Mode
- the SDH can carry ATM (Asynchronous Transfer Mode) cells and this enables information to be sent at a variable bit rate by varying the number of cells transmitted on a given virtual channel. While the route across the network is fixed, only an allowance for the occupancy of a virtual channel is made and physical channels can be pooled and shared by different transactions. Peaks in traffic can therefore cause temporary blocking and provision has to be made for holding the less urgent traffic at nodes in the network and hence operating in a store and forward mode.
- ATM Asynchronous Transfer Mode
- TST Time-Space-Time
- incoming traffic at a nominal 2 Mbit/s rate is read into a memory in arrival order.
- the combined memory for a number, N, of 2 Mbit/s links is the first time stage.
- Traffic is switched to the output time stage and written into a memory associated with the relevant output link by a space stage that is time divided.
- the space stage consists of a highway B bits wide running at a bit rate of P bit/s.
- the bit rate on the highway is:
- the ATMOSPHERIC switch works in a combined STM-ATM environment with separate switch blocks for STM and ATM traffic.
- space switching is by a multi-stage non self routed network and the store and forward function is implemented by content addressable memories on the input side of the switch.
- the STM switch is STS (Space-time-Space) and the space stages are time multiplexed.
- the switch contains a gateway or translation function between the STM and ATM environments.
- TST switch and to make the time stages electronic and the space stage optical, hence an Electronic Time--Optical Space--Electronic Time (ETOSET) switch.
- ETOSET Electronic Time--Optical Space--Electronic Time
- FELC/VLSI Liquid crystal technology
- FELC/VLSI Liquid crystal technology
- optics is used to aid electronic switching by providing highly parallel reconfigurable interconnection paths.
- the transmission interface is an M STM-1 system. This might consist of a higher order STM-M multiplex in which case all the information would be frame synchronised or it might consist of a number of separate multiplexes of order less than STM-M originating at different places for which frames would not be in synchronism. In any event, demultiplexing (disassembly) to the STM-1 (155 Mbit/s level is assumed at the switch interface.
- Switchable entities (a) Demultiplex incoming containers and reassemble then as "switchable entities" (SE) in a form suitable for conveyance to a destination within the switch.
- the simplest "switch” is a memory into which the incoming links write their containers as SEs and the outgoing links pick out what they want for their own purposes and ignore the rest.
- the problem with this is contention for memory access. Whilst the incoming links can be assigned their own memory sectors so that they do not contend with each other, the outgoing links need to access memory at random, leading to contention. If R is the incoming data rate per link and access is in terms of octets, the write rate on input is R/8, while the read rate on output is R*M/8.
- the difficulty can be overcome if the incoming links write their containers into their own sectors of memory and then the total memory is copied en bloc and M-fold to each of the M output links. All that is needed is a means of replicating the input memory and the FELC/VLSI technology provides an optical means of doing this.
- One such means is shown in FIG. 7a (ETOSET--simple replication). Note that no shutters are required because the input memory is replicated redundantly and selection of what is wanted from it is made once this has happened. There is no need to specify or quantise the SE size.
- the output read rate is R/8.
- SR Simple Replication
- the number of ways that the switch can switch is M+2 because in addition to the M outgoing link sectors for transit switching there is a store and forward sector for packet switching and a local delivery sector for local traffic. Actually only M output memory blocks are required, as will be apparent from revised structure (FIG. 14) discussed in the following, whilst still enabling these extra functions to be achieved. Packets can be (a) switched straight through to an outgoing link sector, (b) switched into a store and forward sector, or (c) switched to a local delivery sector for local distribution.
- the store and forward sector contains queues in which packets can be stored awaiting a free slot in an outgoing STM-1. It should be noted that the size of the outgoing memory needs to be sufficient to hold these queues, but as data arrives it can be shifted out of the photosensitive memory area into conventional RAM.
- the total number of shutters is 64 * 2 * M * (M+2).
- the local delivery sector is for 2.048 Mbit/s systems that need to be broken down to the 64 kbit/s level. Once received the 64 kbit/s channels are handled in separate and conventional 64 kbit/s switches and/or multiplexers.
- the ETOSET switch of FIG. 8 has an input plane store (Frame store E to O (electronic to optic) conversion) consisting of an array of FELC/VLSI modulators as described above with reference to the packet switch but loading of the memory is in a normal parallel (RAM) mode rather than by a shift register.
- input plane store Frae store E to O (electronic to optic) conversion
- FIG. 9a shows the timing diagram. Note that incoming link frames are randomly related in time whereas outgoing link frames are synchronised locally. It is necessary to delay traffic by a maximum of 250 microseconds plus the time, ⁇ t, to switch the traffic across the switch. Alternate frames are loaded into alternative rows A and B of the frame store (FIG. 9b) and when a frame is complete it is transferred every 125 microseconds in one parallel operation into the modulator (FELC/VLSI) memory row. Thus each pixel in memory requires three bits, only one of which is connected to the liquid crystal display pad. If all the incoming links are frame synchronised, for example, they come from one high order input multiplex, then it is only necessary to provide storage to buffer ⁇ t worth of incoming data and the buffer storage requirement is much reduced.
- optical space switch design (as outlined in FIG. 7) depends on which of the alternatives discussed above is adopted. It can range in complexity from the arrangement described for the packet switch to the SR design described above.
- the output plane store (received store O to E (optical to electronic) conversion) consists of photodetectors and memory cells as described with reference to the packet switch but again organised as conventional RAM rather than in serial shift register mode.
- FIG. 10a shows the input plane for a simplified situation where there are four incoming STM-1 links, or the equivalent, and each link has a payload of six tributaries, each of which is put into the appropriate number of cells and is to be switched as an entity.
- the destination of each cell-set is indicated in the figure and the incoming tributaries are loaded into the input memory in any order.
- An order that is a direct mapping of their position in the SDM multiplex may be convenient, however the packet traffic could be segregated from the rest.
- FIG. 10b shows two links in the output plane of the switch.
- the output plane has M+2 times the memory cells for the input plane.
- the designation in the boxes indicate which incoming link the output cell information has come from.
- Clearly there is a lot of redundant storage because at any instant in time only a fraction of the output storage is occupied.
- no fan-in optics is required, but there are shutters, and the output memory can be placed at the SLM shutter plane.
- the output traffic order in store does not bear any relationship to the order in which it is required to be transmitted on the output link. However with parallel read-out from the output store this is not a problem.
- each output link needs only one sector's worth of storage whilst with the above arrangement it needs M-1 sectors (it would be M if traffic were to be returned on the link it came by--which could be the case for test traffic) and it is necessary to consider a design in which all the outgoing link traffic is overlaid by fan-in optics on a one sector output store.
- FIG. 10a it is apparent that some of the traffic from links 1 and 2 destined for links 3 and 4 would be switched to the same locations in memory. To avoid this difficulty the input traffic has to be arranged in an order that prevents clashes and two cases can be considered:
- FIG. 11 shows the principle, each input link is assigned areas for output traffic and none of these assigned areas overlap. This is acceptable if the traffic is balanced but if link 1, say, has a lot of traffic for link 3, the link 1 assigned area (row 2) may overflow and there will be a need to "borrow" from another assigned area. Any borrowing involves checking all the other links to avoid clashes. The knock-on effects can be reduced if there is surplus memory both on the input and output sides and in fact FIG.
- SR choice between SR and AIM depends on the relative cost of memory and optics and on the practicality of the no-clash algorithm with AIM. SR might appear to be cheaper and is certainly simpler.
- FIG. 12 shows four incoming links (L1, L2, L3, L4) at the STM-1 level and is a minimal configuration for explanatory purposes.
- the output of each incoming link is copied four-fold into a dedicated area of each output store.
- Each of the four output stores is partitioned so that writing can take place independently to each sector of its four sectors.
- the address information relevant to the outgoing link, y is written into the dedicated area of memory block Mxy.
- the read-out block Ry reads the address information in each of the associated memory block's four sectors and determines which of the content of the memory block is for output on link y. The relevant content of the output store is then read out in line required order and transmitted on the outgoing link. Data that is not intended for link y is ignored.
- the read out block Ry is also responsible for drop and insert for local traffic. For a given two-way circuit the drop operation is handled for the incoming channel by the Ry block that provides the insertion operation for the outgoing channel.
- reformatting can take place as part of the outgoing assembly procedure e.g. primary rate to ATM gateway mode; primary rate to ATM--transparent mode; STM-1 to ATM gateway mode; STM-1 to ATM current mode.
- primary rate to ATM gateway mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM gateway mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM current mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM gateway mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM current mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM gateway mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM current mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM gateway mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM current mode e.g. primary rate to ATM gateway mode
- STM-1 to ATM gateway mode e.g. primary rate to ATM gateway mode
- FIG. 13 shows by way of example and in greater detail the organisation of the first of the memory blocks of FIG. 12.
- the sector M11 is divided into two sub-sections M11A and M11B which are alternately written and read. This duplication is necessary for rephasing the output when the incoming links are not frame synchronised.
- This is similar to the ETOSET arrangement except that storage is duplicated rather than triplicated because there is no need here, as there is in the optical solution, to transfer information from storage cells to the read-out cells.
- control is on a per link basis insofar as all the necessary information to sustain the connection is contained within the SDH multiplex.
- central control module which is used to set up calls and to handle management information but this is not shown in FIG. 12.
- the storage requirement at the STM-1 level is B bits and there are M STM-1 systems, then the storage requirements for the optical solution is (3BM+BM 2 ) and for the electronic solution is 2BM 2 .
- incoming information is written to block M11A while output information is read from block M11B.
- the blocks marked W and R are the write and read address decoders respectively and are shown separately for clarity but in practice can share circuitry. Only the outgoing data in M11B relevant to L1 is read.
- a queue area is shown in FIG. 13 for the store and forward function and this area could be shared between all of the M ⁇ 1 memory block, although the arrangements necessary for sharing are not shown.
- the optical solution requires 2M+M and the electronic solution requires 2M 2 .
- SER over knockout/Gauss are an ability to cope with a mixed ATM/STM environment and a design that needs to make minimum assumptions about traffic situations (i.e. only for the dimensioning of internal queues). In a totally ATM environment, the Knockout/Gauss approaches would be preferable.
- SER and ATMOSPHERIC are both designs that attempt to switch traffic in a mixed ATM/STM environment, although as mentioned above ATMOSPHERIC has separate ATM and STM sections.
- SER is believed to have clear advantages in respect of modularity, simplicity, traffic independence and distribution of control.
- FIG. 14 illustrates the revised ETOSET configuration. It differs from the original version in that:
- connection information is conveyed by the switch in an analogous manner to that proposed for SER. (The central control module which is concerned with path establishment and management is not shown in FIG. 14).
- FIG. 15a shows the source memory organisation as proposed above and parallel read-out and FIG. 15b suggests an alternative serial transfer arrangement for the destination memory.
- the serial arrangement needs 1/nth of the modulator cells of the parallel arrangement, where n is the number of bits serially shifted per frame. Because the number of modulator cells is the major factor in determining the silicon area for the source memory, the serial arrangement requires a lot less silicon. However, if t is switching time of the modulator, the latency of the switch increases by nt. In any event nt must be less than 125 microseconds.
- the arrangement of FIG. 15b is such that the destination memory will need fewer photodetectors and a shift register input. Because the photodetectors in the destination memory are much faster than the modulators in the source memory, the source memory is the determining factor as far as speed is concerned.
- each incoming link is assigned a sector of the input memory and addresses it sequentially in incoming data order.
- sub-sectors or assembly areas
- the input memory requirement is:
- R i replication factor for input memory 3 for ETOSET
- the output storage requirement is:
- R o replication factor for output memory (1 for ETOSET)
- the table shown in FIG. 18 compares the memory requirements for the two situations in units of B. Bearing in mind that B is of the order of 18-19 kbit, with values of N 8 or greater the savings are very significant.
- the number of crosspoints in the shuffle is based on a two stage network as described in "A rotating access switch" M E Beshai, E A Munter, Queuing Performance and Control in ATM (ITC-13). J Cohen and D Pack (eds). Elsevier Science Publications B.V. 1991, pp 53058, and assumed transfer through the shuffle is in serial mode. Because the crosspoints are driven in a fixed sequence, they can be controlled by sets of circulating shift registers with one bit set in each register and there is then only one storage bit per crosspoint.
- the rotating access ATM switch according to Beshai and Munter is for fixed length ATM cells only, whereas ETOSET was intended for a mixture of STM and ATM traffic.
- rate of shuffle for ETOSET It could be at the octet rate, the cell rate (i.e. a six octet rate assuming the cell header is removed) or switch between rates according to the traffic patterns. The latter is considered impractical because different links will have different traffic patterns at any one time. If the octet rate is adopted, ATM cells will cease to be contiguous in memory, and if the cell rate is adopted some of the advantage of shuffling will be lost for STM traffic.
- Memory for each incoming link is provisionally assigned as shown in FIG. 19. It should be noted that in the horizontal direction none of the assignments overlap, and that in each case an equal amount of memory is "self" assigned for the case where the incoming link and the outgoing link are the same. Because it is most unlikely that there will be appreciable test traffic that would need such an assignment, this memory can be regarded as effectively unassigned to be used as the other allocations overflow.
- each incoming link there is a set of pointers, one for each outgoing link, and as memory is allocated to incoming traffic these pointers are advanced.
- FIG. 20 outlines the control arrangement for ETOSET/AIM for an example of four links.
- the input link information is replicated fourfold in the shutter plane and then concentrated at the output into a memory equal in capacity to that needed to store one frame.
- Each plane has optical transmitters and/or receivers so that control information can be carried optically through the switch, dispensing with the need to provide external circuits for control.
- the shutter plane is divided into 16 segments, each segment having a number of shutters equal to the number of memory slots per link; 64 are shown for illustrative purposes.
- Each shutter segment is denoted by Sxy, where x is the number of the input link and y is the number of the output link.
- Control is highly distributed with each input link doing its own control processing independently.
- Each input link needs to know the busy-free status of memory slots in the output link, as discussed above. It communicates with the output links over permanently allocated optical paths through the switch in both directions. (The optical switch is capable of operating back-to-front).
- FIG. 21 shows how each input link has a set of four receivers and one transmitter for end to end communications and a second transmitter for communication with the shutter plane.
- each output link has a set of four receivers and one transmitter for communication with the input planes.
- the shutter plane has only receivers and is told which shutters to open by the input planes.
- each input link needs to read the bit map of the destination output link before allocating a memory slot.
- reading of the bit map is by optical communication across the switch.
- the appropriate shutter may be opened in the shutter plane.
- An alternative means of control is to confine optical communication for control to messages between the input plane and the shutter plane (the output plane is not involved).
- the saving in communication paths is however offset by the need for the different sectors of the input plane to communicate with each other in order to establish the busy/free state of output plane memory elements.
- Such internal input memory plane communication is probably best done by electronic rather than optical means and might make it more difficult to achieve the degree of modularity available to the three plane solution.
- FIG. 22 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows the Simple Electronic Replication case with the addition of a shuffle at the input.
- FIG. 16 shows
- each link's memory in FIG. 22 is divided into four areas, each of which can be written to in parallel from the appropriate incoming bit stream, but incoming information destined for other links is discarded.
- Equation (2) and (4) apply, except that R o is 2 in this case.
- the table in FIG. 23 compares performance without and with shuffle. Here the savings are very significant, greater than that with ETOSET/SR and also greater than that without the shuffle (assuming the community of interest is substantial).
- the output information needs to be sorted before it can be output in the desired sequence over the transmission medium. This applies to any configuration involving shuffling.
- FIG. 24 illustrates in principle how information might be stored in output memory.
- the diagram is for outgoing link 4 and shows the state at time slot 5 after the start of a frame at a time slot 1.
- the number in a memory column represents the link number from which the information came and the number at the side of an entry is the time slot in which it arrived.
- These items of information are related to each other in event registers shown at the bottom of the diagram.
- the event registers are written as part of the data writing-in process. Note that link 2 starts providing information to link 4 after a delay during which it might have had information for another link which would have been discarded at the link 4 interface. Of course there is normally no traffic from link 4 to link 4. Through the event registers, information that is segmented by the shuffling process can be reassembled into the correct contiguous order for output.
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Abstract
Description
P=2N/B Mbit/s
C=(NB).sup.2
M.sub.is =R.sub.i *(B+σ)*N (1)
M.sub.os =R.sub.o *(B+σ)*N (2)
M.sub.i =R.sub.i *B*N (3)
M.sub.o =R.sub.o *B*N.sup.2 (4)
Claims (19)
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Also Published As
Publication number | Publication date |
---|---|
EP0653142B1 (en) | 1997-09-10 |
JPH07509821A (en) | 1995-10-26 |
DE69313861T2 (en) | 1998-01-22 |
EP0653142A1 (en) | 1995-05-17 |
GB2269296A (en) | 1994-02-02 |
WO1994004007A3 (en) | 1994-05-11 |
GB9216412D0 (en) | 1992-09-16 |
DE69313861D1 (en) | 1997-10-16 |
WO1994004007A2 (en) | 1994-02-17 |
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